SummaryObesity associated disorders such as T2D, hypertension and CVD, commonly referred to as the “metabolic syndrome”, are prevalent diseases of industrialized societies. Deranged adipose tissue proliferation and differentiation contribute significantly to the development of these metabolic disorders. Comparatively little however is known, about how these processes influence the development of metabolic disorders. Using a multidisciplinary approach, I plan to elucidate molecular mechanisms underlying the altered adipocyte differentiation and maturation in different models of obesity associated metabolic disorders. Special emphasis will be given to the analysis of gene expression, postranslational modifications and lipid molecular species composition. To achieve this goal, I am establishing several novel methods to isolate pure primary preadipocytes including a new animal model that will allow me to monitor preadipocytes, in vivo and track their cellular fate in the context of a complete organism. These systems will allow, for the first time to study preadipocyte biology, in an in vivo setting. By monitoring preadipocyte differentiation in vivo, I will also be able to answer the key questions regarding the development of preadipocytes and examine signals that induce or inhibit their differentiation. Using transplantation techniques, I will elucidate the genetic and environmental contributions to the progression of obesity and its associated metabolic disorders. Furthermore, these studies will integrate a lipidomics approach to systematically analyze lipid molecular species composition in different models of metabolic disorders. My studies will provide new insights into the mechanisms and dynamics underlying adipocyte differentiation and maturation, and relate them to metabolic disorders. Detailed knowledge of these mechanisms will facilitate development of novel therapeutic approaches for the treatment of obesity and associated metabolic disorders.

Obesity associated disorders such as T2D, hypertension and CVD, commonly referred to as the “metabolic syndrome”, are prevalent diseases of industrialized societies. Deranged adipose tissue proliferation and differentiation contribute significantly to the development of these metabolic disorders. Comparatively little however is known, about how these processes influence the development of metabolic disorders. Using a multidisciplinary approach, I plan to elucidate molecular mechanisms underlying the altered adipocyte differentiation and maturation in different models of obesity associated metabolic disorders. Special emphasis will be given to the analysis of gene expression, postranslational modifications and lipid molecular species composition. To achieve this goal, I am establishing several novel methods to isolate pure primary preadipocytes including a new animal model that will allow me to monitor preadipocytes, in vivo and track their cellular fate in the context of a complete organism. These systems will allow, for the first time to study preadipocyte biology, in an in vivo setting. By monitoring preadipocyte differentiation in vivo, I will also be able to answer the key questions regarding the development of preadipocytes and examine signals that induce or inhibit their differentiation. Using transplantation techniques, I will elucidate the genetic and environmental contributions to the progression of obesity and its associated metabolic disorders. Furthermore, these studies will integrate a lipidomics approach to systematically analyze lipid molecular species composition in different models of metabolic disorders. My studies will provide new insights into the mechanisms and dynamics underlying adipocyte differentiation and maturation, and relate them to metabolic disorders. Detailed knowledge of these mechanisms will facilitate development of novel therapeutic approaches for the treatment of obesity and associated metabolic disorders.

Max ERC Funding

1 607 105 €

Duration

Start date: 2008-07-01, End date: 2013-06-30

Project acronymAftermath

ProjectTHE AFTERMATH OF THE EAST ASIAN WAR OF 1592-1598.

Researcher (PI)Rebekah CLEMENTS

Host Institution (HI)UNIVERSITAT AUTONOMA DE BARCELONA

Call DetailsStarting Grant (StG), SH6, ERC-2017-STG

SummaryAftermath seeks to understand the legacy of the East Asian War of 1592-1598. This conflict involved over 500,000 combatants from Japan, China, and Korea; up to 100,000 Korean civilians were abducted to Japan. The war caused momentous demographic upheaval and widespread destruction, but also had long-lasting cultural impact as a result of the removal to Japan of Korean technology and skilled labourers. The conflict and its aftermath bear striking parallels to events in East Asia during World War 2, and memories of the 16th century war remain deeply resonant in the region. However, the war and its immediate aftermath are also significant because they occurred at the juncture of periods often characterized as “medieval” and “early modern” in the East Asian case. What were the implications for the social, economic, and cultural contours of early modern East Asia? What can this conflict tell us about war “aftermath” across historical periods and about such periodization itself? There is little Western scholarship on the war and few studies in any language cross linguistic, disciplinary, and national boundaries to achieve a regional perspective that reflects the interconnected history of East Asia. Aftermath will radically alter our understanding of the region’s history by providing the first analysis of the state of East Asia as a result of the war. The focus will be on the period up to the middle of the 17th century, but not precluding ongoing effects. The team, with expertise covering Japan, Korea, and China, will investigate three themes: the movement of people and demographic change, the impact on the natural environment, and technological diffusion. The project will be the first large scale investigation to use Japanese, Korean, and Chinese sources to understand the war’s aftermath. It will broaden understandings of the early modern world, and push the boundaries of war legacy studies by exploring the meanings of “aftermath” in the early modern East Asian context.

Aftermath seeks to understand the legacy of the East Asian War of 1592-1598. This conflict involved over 500,000 combatants from Japan, China, and Korea; up to 100,000 Korean civilians were abducted to Japan. The war caused momentous demographic upheaval and widespread destruction, but also had long-lasting cultural impact as a result of the removal to Japan of Korean technology and skilled labourers. The conflict and its aftermath bear striking parallels to events in East Asia during World War 2, and memories of the 16th century war remain deeply resonant in the region. However, the war and its immediate aftermath are also significant because they occurred at the juncture of periods often characterized as “medieval” and “early modern” in the East Asian case. What were the implications for the social, economic, and cultural contours of early modern East Asia? What can this conflict tell us about war “aftermath” across historical periods and about such periodization itself? There is little Western scholarship on the war and few studies in any language cross linguistic, disciplinary, and national boundaries to achieve a regional perspective that reflects the interconnected history of East Asia. Aftermath will radically alter our understanding of the region’s history by providing the first analysis of the state of East Asia as a result of the war. The focus will be on the period up to the middle of the 17th century, but not precluding ongoing effects. The team, with expertise covering Japan, Korea, and China, will investigate three themes: the movement of people and demographic change, the impact on the natural environment, and technological diffusion. The project will be the first large scale investigation to use Japanese, Korean, and Chinese sources to understand the war’s aftermath. It will broaden understandings of the early modern world, and push the boundaries of war legacy studies by exploring the meanings of “aftermath” in the early modern East Asian context.

Max ERC Funding

1 444 980 €

Duration

Start date: 2018-11-01, End date: 2023-10-31

Project acronymBacRafts

ProjectArchitecture of bacterial lipid rafts; inhibition of virulence and antibiotic resistance using raft-disassembling small molecules

SummaryMembranes of eukaryotic cells organize signal transduction proteins into microdomains or lipid rafts whose integrity is essential for numerous cellular processes. Lipid rafts has been considered a fundamental step to define the cellular complexity of eukaryotes, assuming that bacteria do not require such a sophisticated organization of their signaling networks. However, I have discovered that bacteria organize many signaling pathways in membrane microdomains similar to the eukaryotic lipid rafts. Perturbation of bacterial lipid rafts leads to a potent and simultaneous impairment of all raft-harbored signaling pathways. Consequently, the disassembly of lipid rafts in pathogens like Staphylococcus aureus generates a simultaneous inhibition of numerous infection-related processes that can be further explored to control bacterial infections. This unexpected sophistication in membrane organization is unprecedented in bacteria and hence, this proposal will explore the molecular basis of the assembly of bacterial lipid rafts and their role in the infection-related processes. These questions will be addressed in three main goals: First, I will elucidate the molecular components and the mechanism of assembly of bacterial lipid rafts using S. aureus as model organism. Second, I will dissect the molecular basis that links the functionality of the infection-related processes to the integrity of bacterial lipid rafts. Third, my collection of anti-raft small molecules that are able to disrupt lipid rafts will be tested as antimicrobial agents to prevent hospital-acquired infections, abrogate pre-existing infections and develop bacteria-free materials that can be used in clinical settings. I will use a number of molecular approaches in combination with cutting-edge techniques in flow cytometry, cell-imaging and transcriptomics to clarify the architecture and functionality of lipid rafts and demonstrate the feasibility of targeting lipid a new strategy for anti-microbial therapy.

Membranes of eukaryotic cells organize signal transduction proteins into microdomains or lipid rafts whose integrity is essential for numerous cellular processes. Lipid rafts has been considered a fundamental step to define the cellular complexity of eukaryotes, assuming that bacteria do not require such a sophisticated organization of their signaling networks. However, I have discovered that bacteria organize many signaling pathways in membrane microdomains similar to the eukaryotic lipid rafts. Perturbation of bacterial lipid rafts leads to a potent and simultaneous impairment of all raft-harbored signaling pathways. Consequently, the disassembly of lipid rafts in pathogens like Staphylococcus aureus generates a simultaneous inhibition of numerous infection-related processes that can be further explored to control bacterial infections. This unexpected sophistication in membrane organization is unprecedented in bacteria and hence, this proposal will explore the molecular basis of the assembly of bacterial lipid rafts and their role in the infection-related processes. These questions will be addressed in three main goals: First, I will elucidate the molecular components and the mechanism of assembly of bacterial lipid rafts using S. aureus as model organism. Second, I will dissect the molecular basis that links the functionality of the infection-related processes to the integrity of bacterial lipid rafts. Third, my collection of anti-raft small molecules that are able to disrupt lipid rafts will be tested as antimicrobial agents to prevent hospital-acquired infections, abrogate pre-existing infections and develop bacteria-free materials that can be used in clinical settings. I will use a number of molecular approaches in combination with cutting-edge techniques in flow cytometry, cell-imaging and transcriptomics to clarify the architecture and functionality of lipid rafts and demonstrate the feasibility of targeting lipid a new strategy for anti-microbial therapy.

SummaryNecrosis triggers an inflammatory response driven by macrophages that normally contributes to tissue repair but, under certain conditions, can induce a state of chronic inflammation that forms the basis of many diseases. In addition, dendritic cell (DC)-mediated presentation of antigens from necrotic cells can trigger adaptive immunity in infection-free situations, such as autoimmunity or therapy-induced tumour rejection. Recently, we and others have identified the myeloid C-type lectin receptors (CLRs) CLEC9A (DNGR-1), in DC, and Mincle, in macrophages, as receptors for necrotic cells that can signal via the Syk kinase. Previous studies on similar Syk-coupled CLRs showed that Dectin-1 and Dectin-2 can induce innate and adaptive immune responses. We thus hypothesise that recognition of cell death by myeloid Syk-coupled CLRs is at the root of immune pathologies associated with accumulation of dead cells. The overall objective of this proposal is to investigate necrosis sensing by myeloid cells as a trigger of immunity and to study the underlying molecular mechanisms. Our first goal is to characterise signalling and gene induction via CLEC9A as a model necrosis receptor in DCs. Second, we will investigate the role of myeloid Syk-coupled necrosis-sensing CLRs in animal models of atherosclerosis, lupus and immunity to chemotherapy-treated tumours. Our preliminary data suggest that additional receptors can couple necrosis recognition to the Syk pathway in DC; thus, our third aim is to identify novel myeloid Syk-coupled receptors for necrotic cells. Characterisation of the outcomes of sensing necrosis by myeloid Syk-coupled receptors and their effect on the proposed pathologies promises to identify new mechanisms and targets for the treatment of these diseases.

Necrosis triggers an inflammatory response driven by macrophages that normally contributes to tissue repair but, under certain conditions, can induce a state of chronic inflammation that forms the basis of many diseases. In addition, dendritic cell (DC)-mediated presentation of antigens from necrotic cells can trigger adaptive immunity in infection-free situations, such as autoimmunity or therapy-induced tumour rejection. Recently, we and others have identified the myeloid C-type lectin receptors (CLRs) CLEC9A (DNGR-1), in DC, and Mincle, in macrophages, as receptors for necrotic cells that can signal via the Syk kinase. Previous studies on similar Syk-coupled CLRs showed that Dectin-1 and Dectin-2 can induce innate and adaptive immune responses. We thus hypothesise that recognition of cell death by myeloid Syk-coupled CLRs is at the root of immune pathologies associated with accumulation of dead cells. The overall objective of this proposal is to investigate necrosis sensing by myeloid cells as a trigger of immunity and to study the underlying molecular mechanisms. Our first goal is to characterise signalling and gene induction via CLEC9A as a model necrosis receptor in DCs. Second, we will investigate the role of myeloid Syk-coupled necrosis-sensing CLRs in animal models of atherosclerosis, lupus and immunity to chemotherapy-treated tumours. Our preliminary data suggest that additional receptors can couple necrosis recognition to the Syk pathway in DC; thus, our third aim is to identify novel myeloid Syk-coupled receptors for necrotic cells. Characterisation of the outcomes of sensing necrosis by myeloid Syk-coupled receptors and their effect on the proposed pathologies promises to identify new mechanisms and targets for the treatment of these diseases.

Max ERC Funding

1 297 671 €

Duration

Start date: 2010-12-01, End date: 2016-08-31

Project acronymCOhABIT

ProjectConsequences of helminth-bacterial interactions

Researcher (PI)Nicola Harris

Host Institution (HI)ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE

Call DetailsStarting Grant (StG), LS6, ERC-2012-StG_20111109

Summary"Throughout evolution both intestinal helminths and commensal bacteria have inhabited our intestines. This ""ménage à trois"" situation is likely to have exerted a strong selective pressure on the development of our metabolic and immune systems. Such pressures remain in developing countries, whilst the eradication of helminths in industrialized countries has shifted this evolutionary balance—possibly underlying the increased development of chronic inflammatory diseases. We hypothesize that helminth-bacterial interactions are a key determinant of healthy homeostasis.
Preliminary findings from our laboratory indicate that helminth infection of mice alters the abundance and diversity of intestinal bacteria and impacts on the availability of immuno-modulatory metabolites; this altered environment correlates with a direct health advantage, protecting against inflammatory diseases such as asthma and rheumatoid arthritis. We intend to validate and extend these data in humans by performing bacterial phlyogenetic and metabolic analysis of stool samples collected from a large cohort of children living in a helminth endemic region of Ecuador. We further propose to test our hypothesis that helminth-bacterial interactions contribute to disease modulation using experimental models of infection and disease. We plan to develop and utilize mouse models to elucidate the mechanisms through which bacterial dysbiosis and helminth infection influence the development of chronic inflammatory diseases. These models will be utilized for germ-free and recolonization experiments, investigating the relative contribution of bacteria versus helminthes to host immunity, co-metabolism and disease modulation.
Taking a trans-disciplinary approach, this research will break new ground in our understanding of the crosstalk and pressures between intestinal helminth infection and commensal bacterial communities, and the implications this has for human health."

"Throughout evolution both intestinal helminths and commensal bacteria have inhabited our intestines. This ""ménage à trois"" situation is likely to have exerted a strong selective pressure on the development of our metabolic and immune systems. Such pressures remain in developing countries, whilst the eradication of helminths in industrialized countries has shifted this evolutionary balance—possibly underlying the increased development of chronic inflammatory diseases. We hypothesize that helminth-bacterial interactions are a key determinant of healthy homeostasis.
Preliminary findings from our laboratory indicate that helminth infection of mice alters the abundance and diversity of intestinal bacteria and impacts on the availability of immuno-modulatory metabolites; this altered environment correlates with a direct health advantage, protecting against inflammatory diseases such as asthma and rheumatoid arthritis. We intend to validate and extend these data in humans by performing bacterial phlyogenetic and metabolic analysis of stool samples collected from a large cohort of children living in a helminth endemic region of Ecuador. We further propose to test our hypothesis that helminth-bacterial interactions contribute to disease modulation using experimental models of infection and disease. We plan to develop and utilize mouse models to elucidate the mechanisms through which bacterial dysbiosis and helminth infection influence the development of chronic inflammatory diseases. These models will be utilized for germ-free and recolonization experiments, investigating the relative contribution of bacteria versus helminthes to host immunity, co-metabolism and disease modulation.
Taking a trans-disciplinary approach, this research will break new ground in our understanding of the crosstalk and pressures between intestinal helminth infection and commensal bacterial communities, and the implications this has for human health."

Max ERC Funding

1 480 612 €

Duration

Start date: 2013-04-01, End date: 2018-03-31

Project acronymCRC PROGRAMME

ProjectDissecting the roles of the beta-catenin and Tcf genetic programmes during colorectal cancer progression

SummaryMost colorectal cancers (CRCs) are initiated by activating mutations in components of the Wnt signalling pathway. Physiological Wnt signals are required for the specification and maintenance of the stem and progenitor cell compartments of the intestinal crypts. We demonstrated that early colorectal lesions exhibit a constitutive Wnt target gene programme, which is very similar to that of normal intestinal stem and progenitor cells. We originally proposed that colorectal adenomas behave as clusters of intestinal cells locked into a constitutive crypt progenitor phenotype. Given the prevalence of Wnt signalling mutations in CRC, an outstanding endeavour is the characterization of the similarities and differences in the instructions dictated by beta-catenin and Tcf to normal intestinal cells vs. CRC cells. Here, we propose to systematically compare and catalogue the beta-catenin/Tcf genetic programmes in intestinal progenitor/stem cells, intestinal adenomas and late CRCs. Transcriptomic analysis of isolated normal progenitor cells and tumor cell populations combined with bioinformatic analysis of gene regulatory networks will allow us to workout the hierarchical interactions downstream of beta-catenin and Tcf. Moreover, functional analysis of key beta-catenin/Tcf target genes using genetically modified mice models will help us to pinpoint which Wnt-controlled functions are essential for tumor maintenance and progression in vivo. Moreover, we seek to understand the tumor suppressor role of EphB2 and EphB3 receptors, two beta-catenin/Tcf target genes in normal crypts and benign colorectal adenomas, that block cancer progression by compartmentalizing tumor cells at the onset of CRC. Overall, our results will shed light on the relationship between stem/progenitor cells and cancer and hold potential for the future development of both therapeutic and diagnostic tools.

Most colorectal cancers (CRCs) are initiated by activating mutations in components of the Wnt signalling pathway. Physiological Wnt signals are required for the specification and maintenance of the stem and progenitor cell compartments of the intestinal crypts. We demonstrated that early colorectal lesions exhibit a constitutive Wnt target gene programme, which is very similar to that of normal intestinal stem and progenitor cells. We originally proposed that colorectal adenomas behave as clusters of intestinal cells locked into a constitutive crypt progenitor phenotype. Given the prevalence of Wnt signalling mutations in CRC, an outstanding endeavour is the characterization of the similarities and differences in the instructions dictated by beta-catenin and Tcf to normal intestinal cells vs. CRC cells. Here, we propose to systematically compare and catalogue the beta-catenin/Tcf genetic programmes in intestinal progenitor/stem cells, intestinal adenomas and late CRCs. Transcriptomic analysis of isolated normal progenitor cells and tumor cell populations combined with bioinformatic analysis of gene regulatory networks will allow us to workout the hierarchical interactions downstream of beta-catenin and Tcf. Moreover, functional analysis of key beta-catenin/Tcf target genes using genetically modified mice models will help us to pinpoint which Wnt-controlled functions are essential for tumor maintenance and progression in vivo. Moreover, we seek to understand the tumor suppressor role of EphB2 and EphB3 receptors, two beta-catenin/Tcf target genes in normal crypts and benign colorectal adenomas, that block cancer progression by compartmentalizing tumor cells at the onset of CRC. Overall, our results will shed light on the relationship between stem/progenitor cells and cancer and hold potential for the future development of both therapeutic and diagnostic tools.

Max ERC Funding

1 602 817 €

Duration

Start date: 2008-09-01, End date: 2013-08-31

Project acronymCTLANDROS

ProjectReactive Oxygen Species in CTL-mediated Cell Death: from Mechanism to Applications

Researcher (PI)Denis Martinvalet

Host Institution (HI)UNIVERSITE DE GENEVE

Call DetailsStarting Grant (StG), LS6, ERC-2010-StG_20091118

SummaryCytotoxic T lymphocytes (CTL) and natural killer (NK) cells release granzyme and perforin from cytotoxic granules into the immune synapse to induce apoptosis of target cells that are either virus-infected or cancerous. Granzyme A activates a caspase-independent apoptotic pathway and induces mitochondrial damage characterized by superoxide anion production and loss of the mitochondrial transmembrane potential, without disrupting the integrity of the mitochondrial outer membrane; while causing single-stranded DNA damage. GzmB induces both caspase-dependent and caspase-independent cell death. In the caspase-dependent pathway, mitochondrial functions are altered as evidenced by the loss of mitochondrial transmembrane potential and the generation of reactive oxygen species (ROS). The mitochondrial outer membrane (MOM) is disrupted, resulting in the release of apoptogenic factors. To date, research on mitochondrial-dependent apoptosis has focused on mitochondrial outer membrane permeabilization (MOMP) however whether the generation of ROS is incidental or essential to the execution of apoptosis remains unclear. Like human GzmA, human GzmB promotes cell death in a ROS-dependent manner. Preliminary data suggest that human GzmB can induce ROS in a MOMP-independent manner as Bax and Bak double knockout MEF cells treated with human GzmB and perforin still display a robust ROS production and dye in an ROS-dependent manner. Since GzmA and GzmB induce cell death in a ROS-dependent manner, we hypothesize that oxygen free radicals are central to the execution of programmed cell death induced by the cytotoxic granules. Therefore, the goal of this proposal is to dissect the key molecular events triggered by ROS that lead to Citotoxic Tcell-induced target cell death. A combination of biochemical, genetic and proteomic approaches in association with Electron Spin Resonance (ESR) spectroscopy methodology will be used to unravel the essential role ROS play in CTL-mediated killing.

Cytotoxic T lymphocytes (CTL) and natural killer (NK) cells release granzyme and perforin from cytotoxic granules into the immune synapse to induce apoptosis of target cells that are either virus-infected or cancerous. Granzyme A activates a caspase-independent apoptotic pathway and induces mitochondrial damage characterized by superoxide anion production and loss of the mitochondrial transmembrane potential, without disrupting the integrity of the mitochondrial outer membrane; while causing single-stranded DNA damage. GzmB induces both caspase-dependent and caspase-independent cell death. In the caspase-dependent pathway, mitochondrial functions are altered as evidenced by the loss of mitochondrial transmembrane potential and the generation of reactive oxygen species (ROS). The mitochondrial outer membrane (MOM) is disrupted, resulting in the release of apoptogenic factors. To date, research on mitochondrial-dependent apoptosis has focused on mitochondrial outer membrane permeabilization (MOMP) however whether the generation of ROS is incidental or essential to the execution of apoptosis remains unclear. Like human GzmA, human GzmB promotes cell death in a ROS-dependent manner. Preliminary data suggest that human GzmB can induce ROS in a MOMP-independent manner as Bax and Bak double knockout MEF cells treated with human GzmB and perforin still display a robust ROS production and dye in an ROS-dependent manner. Since GzmA and GzmB induce cell death in a ROS-dependent manner, we hypothesize that oxygen free radicals are central to the execution of programmed cell death induced by the cytotoxic granules. Therefore, the goal of this proposal is to dissect the key molecular events triggered by ROS that lead to Citotoxic Tcell-induced target cell death. A combination of biochemical, genetic and proteomic approaches in association with Electron Spin Resonance (ESR) spectroscopy methodology will be used to unravel the essential role ROS play in CTL-mediated killing.

Max ERC Funding

1 500 000 €

Duration

Start date: 2011-05-01, End date: 2016-04-30

Project acronymERINFLAMMATION

ProjectInflammatory signals emerging from the endoplasmic reticulum

Researcher (PI)Fabio Martinon

Host Institution (HI)UNIVERSITE DE LAUSANNE

Call DetailsStarting Grant (StG), LS6, ERC-2011-StG_20101109

SummaryThe endoplasmic reticulum (ER) serves many general functions, including the facilitation of protein folding and the transport of synthesized proteins, but it also has an important and more specialized role in sensing cellular stress. ER-stress identifies a group of signals that induce a transcriptional program enabling cells to survive protein overload and injury in the ER. This highly coordinated response involves three parallel signaling branches localized at the ER, namely IRE1, ATF6 and PERK.
New findings suggest that these signaling pathways may regulate cellular processes independently of the ER-stress response. We have previously shown that some innate immune receptors such as Toll-like receptors specifically activate the IRE1 signaling pathway to enhance cytokine production. However, this is an emerging field of research and little is known on the specific nature of ER-signaling pathways and their function in regulating pathways in absence of a classical ER-stress response.
The longterm goals of this proposal are to elucidate the molecular mechanisms and pathways emerging from the ER and regulating innate immune responses, and to address the physiological role of specific ER-signaling pathways in inflammation. Three complementary research sub-projects were designed. The first sub-project will identify and characterize compounds and conditions that trigger specific ER-signaling pathways. The second sub-project focuses on the biochemical characterization of signaling pathways emerging from the ER-associated kinases IRE1 and PERK. The third sub-project is aimed at investigating mechanisms by which ER-signaling pathways affect innate immune and inflammatory responses.
The knowledge gained from this study will provide a better understanding of the mechanisms by which the ER and the cytosol interact to orchestrate physiological responses that help the organism to cope with infections and pathogenic insults.

The endoplasmic reticulum (ER) serves many general functions, including the facilitation of protein folding and the transport of synthesized proteins, but it also has an important and more specialized role in sensing cellular stress. ER-stress identifies a group of signals that induce a transcriptional program enabling cells to survive protein overload and injury in the ER. This highly coordinated response involves three parallel signaling branches localized at the ER, namely IRE1, ATF6 and PERK.
New findings suggest that these signaling pathways may regulate cellular processes independently of the ER-stress response. We have previously shown that some innate immune receptors such as Toll-like receptors specifically activate the IRE1 signaling pathway to enhance cytokine production. However, this is an emerging field of research and little is known on the specific nature of ER-signaling pathways and their function in regulating pathways in absence of a classical ER-stress response.
The longterm goals of this proposal are to elucidate the molecular mechanisms and pathways emerging from the ER and regulating innate immune responses, and to address the physiological role of specific ER-signaling pathways in inflammation. Three complementary research sub-projects were designed. The first sub-project will identify and characterize compounds and conditions that trigger specific ER-signaling pathways. The second sub-project focuses on the biochemical characterization of signaling pathways emerging from the ER-associated kinases IRE1 and PERK. The third sub-project is aimed at investigating mechanisms by which ER-signaling pathways affect innate immune and inflammatory responses.
The knowledge gained from this study will provide a better understanding of the mechanisms by which the ER and the cytosol interact to orchestrate physiological responses that help the organism to cope with infections and pathogenic insults.

SummaryIn the last decade the approaches of the global history have been emphasized in order to visualize the progress, form and method which historians have undertaken when carrying out ambitious research projects to analyse and compare diverse geographical and cultural areas of Asia and Europe. But when dealing with comparisons and cross-cultural studies in Europe and Asia, some scholarly works have exceeded of ambiguities when defining geographical units as well as chronology. In this project I examine perceptions and dialogues between China and Europe by analysing strategic geopolitical sites which fostered commerce, consumption and socioeconomic networks between China and Europe through a particular case study: Macau, connecting with South China, and Marseille in Mediterranean Europe.
How did foreign merchant networks and trans-national communities of Macau and Marseille operate during the eighteenth century and contribute to somehow transfer respectively European and Chinese socio-cultural habits and forms in local population? What was the degree and channels of consumption of European goods in China and Chinese goods in Europe? These are the main questions to answer during my research to explore the bilateral Sino-European trade relations and how the trans-national dimension of exotic commodities changed tastes by creating a new type of global consumerism.
Such concrete comparison can help to narrow the gap that some researchers have created when widely analysing differences between Asia and Europe without a specific geographical and chronological delineation. The major novelty of this project is based on the use of Chinese and European sources to study changes in consumer behaviour. The principal investigator of the project works in China which is and added value for the achievement of outstanding results. So the expected results will bring an obvious breakthrough by adding the specific part of the project in which each team member will work.

In the last decade the approaches of the global history have been emphasized in order to visualize the progress, form and method which historians have undertaken when carrying out ambitious research projects to analyse and compare diverse geographical and cultural areas of Asia and Europe. But when dealing with comparisons and cross-cultural studies in Europe and Asia, some scholarly works have exceeded of ambiguities when defining geographical units as well as chronology. In this project I examine perceptions and dialogues between China and Europe by analysing strategic geopolitical sites which fostered commerce, consumption and socioeconomic networks between China and Europe through a particular case study: Macau, connecting with South China, and Marseille in Mediterranean Europe.
How did foreign merchant networks and trans-national communities of Macau and Marseille operate during the eighteenth century and contribute to somehow transfer respectively European and Chinese socio-cultural habits and forms in local population? What was the degree and channels of consumption of European goods in China and Chinese goods in Europe? These are the main questions to answer during my research to explore the bilateral Sino-European trade relations and how the trans-national dimension of exotic commodities changed tastes by creating a new type of global consumerism.
Such concrete comparison can help to narrow the gap that some researchers have created when widely analysing differences between Asia and Europe without a specific geographical and chronological delineation. The major novelty of this project is based on the use of Chinese and European sources to study changes in consumer behaviour. The principal investigator of the project works in China which is and added value for the achievement of outstanding results. So the expected results will bring an obvious breakthrough by adding the specific part of the project in which each team member will work.

SummaryGlioma is the most common and aggressive tumour of the brain and its most malignant form, glioblastoma multiforme, is nowadays virtually not curable. Very little is known about glioma genesis and progression at the molecular level and not much progress has been achieved in the treatment of this disease during the last years. The understanding of the molecular mechanisms involved in the biology of glioma is essential for the development of successful and rational therapeutic strategies. Our project aims to: 1- Study the role of the TGF-beta, Shh, Notch, and Wnt signal transduction pathways in glioma. These pathways have been implicated in glioma but still not much is known about their specific mechanisms of action. 2- Study of a cell population within the tumour mass that has stem-cell-like characteristics, the glioma stem cells, and how the four mentioned pathways regulate their biology. 3- Study the role of a transcription factor, FoxG1, that has an important oncogenic role in some gliomas and that it is regulated by the four mentioned pathways interconnecting some of them. Our approach will be based on a tight collaboration with clinical researchers of our hospital and the study of patient-derived tumours. We will analyse human biopsies, generate primary cultures of human tumour cells, isolate the stem-cell-like population of patient-derived gliomas and generate mouse models for glioma based on the orthotopical inoculation of human glioma stem cells in the mouse brain to generate tumours with the same characteristics as the original human tumour. In addition, we will also study genetically modified mouse models and established cell lines. We expect that our results will help understand the biology of glioma and cancer, and we aspire to translate our discoveries to a more clinical ambit identifying molecular markers of diagnosis and prognosis, markers of response to therapies, and unveil new therapeutic targets against this deadly disease.

Glioma is the most common and aggressive tumour of the brain and its most malignant form, glioblastoma multiforme, is nowadays virtually not curable. Very little is known about glioma genesis and progression at the molecular level and not much progress has been achieved in the treatment of this disease during the last years. The understanding of the molecular mechanisms involved in the biology of glioma is essential for the development of successful and rational therapeutic strategies. Our project aims to: 1- Study the role of the TGF-beta, Shh, Notch, and Wnt signal transduction pathways in glioma. These pathways have been implicated in glioma but still not much is known about their specific mechanisms of action. 2- Study of a cell population within the tumour mass that has stem-cell-like characteristics, the glioma stem cells, and how the four mentioned pathways regulate their biology. 3- Study the role of a transcription factor, FoxG1, that has an important oncogenic role in some gliomas and that it is regulated by the four mentioned pathways interconnecting some of them. Our approach will be based on a tight collaboration with clinical researchers of our hospital and the study of patient-derived tumours. We will analyse human biopsies, generate primary cultures of human tumour cells, isolate the stem-cell-like population of patient-derived gliomas and generate mouse models for glioma based on the orthotopical inoculation of human glioma stem cells in the mouse brain to generate tumours with the same characteristics as the original human tumour. In addition, we will also study genetically modified mouse models and established cell lines. We expect that our results will help understand the biology of glioma and cancer, and we aspire to translate our discoveries to a more clinical ambit identifying molecular markers of diagnosis and prognosis, markers of response to therapies, and unveil new therapeutic targets against this deadly disease.